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Transcript
Application Note 90
April 2002
Current Sources for Fiber Optic Lasers
A Compendium of Pleasant Current Events
Jim Williams, Linear Technology Corporation
INTRODUCTION
A large group of fiber optic lasers are powered by DC
current. Laser drive is supplied by a current source with
modulation added further along the signal path. The
current source, although conceptually simple, constitutes
an extraordinarily tricky design problem. There are a
number of practical requirements for a fiber optic current
source and failure to consider them can cause laser and/
or optical component destruction.
Protection features must be included to prevent laser and
optical component damage. The laser, an expensive and
delicate device, must be protected under all conditions,
including supply ramp up and down, improper control
input commands, open or intermittent load connections
and “hot plugging.”
Detailed Discussion of Performance Issues
Design Criteria for Fiber Optic Laser Current Sources
It is useful to expand on the above cursory discussion to
clarify design goals. As such, each previously called out
issue is treated in greater detail below.
Figure 1 shows a conceptual laser current source. Inputs
include a current output programming port, an output
current clamp and an enable command. Laser current is
the sole output. This block diagram is deceptively simple.
In practice, a laser current source must meet a number of
practical requirements, some quite subtle. The key to a
successful design is a thorough understanding of individual system requirements. Various approaches suit
different sets of freedoms and constraints, although all
must address some basic concerns.
Required Power Supply
The available power supply should be defined. A single rail
5V supply is presently the most common and desirable.
Supply tolerances, typically ±5%, must be accounted for.
System distribution voltage drops may result in surprisingly low rail voltages at the point of load. Occasionally,
split rails are available, although this is relatively rare.
Additionally, split rail operation can complicate laser protection, particularly during supply sequencing. See “Laser
Protection Features” below for additional comment.
IOUT PROGRAM
TYPICALLY 0V TO 2.5V
IOUT CLAMP
TYPICALLY 0V TO 2.5V
ENABLE
1V TO 5V = OFF
0V = ON
(THIS FUNCTION CAN BE
BUILT INTO CIRCUIT BLOCK)
IOUT TO LASER
TYPICALLY
0 TO 250mA
OR 0 TO 2.5A
AN90 F01
Figure 1. Conceptual Laser Current Source is
Deceptively Simple. Practical System Issues and
Laser Vulnerability Necessitate Careful Design
There are two basic sets of concerns for laser current
sources: performance and protection. Performance issues include the current source’s magnitude and stability
under all conditions, output connection restrictions, voltage compliance, efficiency, programming interface and
power requirements.
Output Current Capability
Low power lasers operate on less than 250mA. Higher
power types can require up to 2.5A.
Output Voltage Compliance
Current source output voltage compliance must be able to
accomodate the laser’s forward junction drop and any
additional drops in the drive path. Typically, voltage compliance of 2.5V is adequate.
, LTC and LT are registered trademarks of Linear Technology Corporation.
AN90-1
Application Note 90
Efficiency
Heat build up in fiber optic systems is often a concern due
to space limitations. Accordingly, current source efficiency can be an issue. At low current, linear regulation is
often adequate. Switching regulator based approaches
may be necessary at higher current.
Laser Connection
In some cases, the laser may float off ground; other
applications require grounded anode or cathode operation. Grounding the anode seemingly mandates a negative
supply but single rail operation can be retained if switching
regulator techniques are employed.
Output Current Programming
Output current is set by a programming port voltage. The
voltage may be derived from a potentiometer, DAC or
filtered PWM. Typically, a range of 0V to 2.5V corresponds
to 0A to 250mA or 0A to 2.5A. Set point accuracy is usually
within 0.5%, although better tolerances are readily achievable. Output current stability, discussed below, is considerably tighter.
Stability
The current source should be well regulated against line,
load and temperature changes. Line and load induced
variations should be held well within 0.05%, with typical
temperature drifts of 0.01%. Judicious component choice
can considerably improve these figures.
Noise
Current source noise, which can modulate laser output,
must be minimized. Typically, noise bandwidth to 100MHz
is of interest. A linearly regulated current source has
inherently low noise and usually presents no problems.
Switching regulator based current sources require special
techniques to maintain low noise.
Transient Response
The current source does not need fast transient response
but it cannot overshoot the programmed current under
any circumstances. Such overshoots can damage the
laser or associated optical components.
Detailed Discussion of Laser Protection Issues
Overshoot
As noted above, outputs overshooting the nominal programmed current can be destructive. Any possible combination of improper control input or power supply turn on/
off characteristics must be accounted for. Also, any spurious laser current under any condition is impermissible.
Note that portions of the current source circuitry may have
undesired and unpredictable responses during supply
ramp up/down, complicating design.
Enable
An enable line allows shutting the current source output
off. The enable line can also be used to hold current output
off during supply ramp up, preventing undesired outputs.
This can be tricky because the enable signal circuitry may
be powered by the same supply that runs the laser. The
enable signal must reliably operate independent of power
supply turn-on profile. Optionally, the enable function can
be self-contained within the current source, eliminating
the necessity to generate this signal.
Output Current Clamp
The output current clamp sets maximum output current,
overriding the output current programming command.
This voltage controlled input can be set by a potentiometer, DAC or filtered PWM.
Open Laser Protection
An unprotected current source’s output rises to maximum
voltage if the load is disconnected. This circumstance can
lead to “hot plugging” the laser, a potentially destructive
event. Intermittent laser connections can produce similar
undesirable results. The current source output should
latch off if the load disconnects. Recycling power clears
the latch but only if the load has been established.
The preceding discussion dictates considerable care when
designing laser current sources. The delicate, expensive
load, combined with the uncertainties noted, should promote an aura of thoughtful caution.1 The following circuit
examples (hopefully) maintain this outlook while simultaneously presenting practical, usable circuits. A variety of
approaches are shown, in keeping with the broad area of
Note 1. “For Fools Rush in Where Angels Fear to Tread.” An essay on
criticism, A. Pope. 1711.
AN90-2
Application Note 90
application. The designs can be directly utilized or serve as
starting points for specific cases.
proach 1W under some conditions. Many applications
permit this but some situations require heating minimization. Figure 3 minimizes heating by replacing Q1 with a
step-down switching regulator. The switched mode power
delivery eliminates almost all of the transistor’s heat.
Basic Current Source
Figure 2, a basic laser current source, supplies up to
250mA via Q1. This circuit requires both laser terminals to
float. The amplifier controls laser current by maintaining
the 1Ω shunt voltage at a potential dictated by the programming input. Local compensation at the amplifier
stabilizes the loop and the 0.1µF capacitor filters input
commands, assuring the loop never slew limits. This
precaution prevents overshoot due to programming input
dynamics. The enable input turns off the current source by
simultaneously grounding Q1’s base and starving the
amplifier’s “+” input while biasing the “–” input high. This
combination also insures the amplifier smoothly ramps to
the desired output current when enable switches low. The
enable input must be addressed by an external “watchdog” which switches after the power supply has been
verified to be within operating limits. Because the external
circuitry may operate from the same supply as the current
source, the enable threshold is set at 1V. The 1V threshold
assures the enable input will dominate the current source
output at low supply voltages during power turn on. This
prevents spurious outputs due to unpredictable amplifier
behavior below minimum supply voltage.
The figure shows similarities to Figure 2’s linear approach,
except for the LTC1504 switching regulator’s addition. It
is useful to liken the switching regulator’s input (VCC),
feedback (FB) and output (VSW) to the transistor’s collector, base and emitter. This analogy reveals the two circuits
to have very similar operating characteristics, with the
switched mode version enhancing efficiency. The
LTC1504’s output LC filter introduces phase shift, necessitating attention to loop compensation. The amplifier’s
local rolloff is similar to Figure 2, although phase leading
AC feedback elements (0.01µF and 0.033µF capacitors)
are required for good loop damping. In all other respects,
including enable and programming input considerations,
this circuit’s operation is identical to Figure 2.
Grounded Cathode Current Source
Figure 4 allows the laser’s cathode to be grounded, as is
sometimes required, by sensing anode current. It utilizes
A1, a device with 500mA output capability and programmable output current limit. A1 senses output current
across the 1Ω shunt, with limiting controlled by the
circuit’s current programming input. A1 is set up as a
unity-gain follower with respect to the laser, allowing its
positive input to serve as a laser voltage clamp input. At
laser voltages below the VCLAMP input, A1 appears as a
current source, controlled by the current programming
High Efficiency Basic Current Source
The preceding circuit uses Q1’s linear regulation to close
the feedback loop. This approach offers simplicity at the
expense of efficiency. Q1’s power dissipation can ap-
10k
INPUT
0V TO 2.5V =
0mA TO 250mA
10k*
0.1µF
Q2
2N3904
80.6K*
5V
+
330Ω
LT1006
10K*
–
* = 1% METAL FILM RESISTOR
Q1
FZT-849
1000pF
100k
1Ω
1%
= 1N4148
= LASER
ENABLE
OFF = 1V TO 5V
ON = 0V
3k
AN90 F02
Figure 2. Basic Current Source Requires Off-Ground Operation of Laser Terminals. Amplifier Controls Current
by Comparing 0.1Ω Shunt to Input. Biasing Enable Until Supply is Verified Prevents Spurious Outputs
AN90-3
Application Note 90
5V
5V
+
22µF
10k
71k
SHDN
10k
ENABLE
OFF = 1V TO 5V
ON = 0V
2N3904
FB
VCC
IMAX
LTC1504A
L1
VSW
GND
+
100µF
0.01µF
* = 1% METAL FILM RESISTOR
L1 = 47µH, SUMIDA CD54-470
= 1N4148
0.033µF
10k
= LASER
10k
+
LT1006
10k*
INPUT
0V TO 2.5V =
0mA TO 250mA
–
0.02µF
80.6k*
0.1µF
1Ω
1%
10k*
AN90 F03
Figure 3. Switching Regulator Replaces Figure 2’s Q1, Providing Higher
Efficiency. Feedback Control and Enable Input Considerations are as Before
ENABLE
0 = ON
1V TO 5V = OFF
INPUT
0VIN TO 2VIN =
0mA TO 250mA OUT
5V
10k
10k
10k
10k
1µF
5V
VSINK
VCLAMP
0VIN TO 2.5VIN =
0VOUT TO 2.5VOUT
10k
+
VSRC
SENSE –
1µF
SENSE +
A1
LT1970
–
1Ω
OUT
GND
EN
– 5V
1N5817
100Ω
1N4001
NPN = 2N3904
PNP = FZT-749
AN90 F04
= LASER
1N4148
Figure 4. LT1970 Power Ampifier/Current Source Permits Grounding Laser Cathode, Although Requiring Split Rails.
Appropriate Modifications would Allow Grounded Anode Operation. Enable Input Must be Biased Until Supplies are Verified
AN90-4
Application Note 90
input’s setting. At laser voltages equaling or above the
VCLAMP input, A1 is a voltage source, controlled by VCLAMP’s
value. This permits the VCLAMP input to limit maximum
voltage across the laser terminals.
Fully Protected, Self-Enabled, Grounded Cathode
Current Source
All of Figure 5’s elements are repeated in Figure 6; no
additional comment on them is necessary. However, three
new features appear, allowing this circuit to operate in a
fully protected and self-contained fashion. The circuit
monitors its power supply and “self-enables” when the
supply is within limits, eliminating the “enable” port and
the external “watchdog” previously required. A settable
current clamp and open laser protection prevent laser
damage.
The enable function operates similarly to previous descriptions and the 1µF capacitors restrict output movement to safe, well damped speeds. The diode shunting the
laser prevents reverse bias during power supply sequencing. The 1N5817 protects against uncontrolled positive
outputs if the negative supply drops out or sequences too
slowly. This circuit’s simplicity and laser connection versatility (appropriate modifications permit grounded anode
operation) are attractive but A1’s negative supply requirement may be detrimental. The negative supply complicates the external “watchdog” circuitry required for the
enable input. In the worst case, it simply may not be
available in the host system.
The self-enable is designed around an LT1431 shunt
regulator. It has the highly desirable property of maintaining a predictable open collector output when operating
below its minimum supply voltage. At initial turn on,
supply voltage is very low (e.g., 1V), the LT1431’s output
does not switch and current flows to Q3’s base. Q3 turns
on, preventing Q1’s base from receiving bias. Additionally,
the circuit’s current programming input is pulled down
and A1’s “–” input is driven. This arrangement ensures
that the laser cannot receive current until Q3 turns off.
Also, when Q3 does go off, A1’s output will cleanly ramp
up to the desired programmed current. The resistor values
at the LT1431’s “REF” input dictate the device will go low
when VSUPPLY passes through 4V. This potential ensures
proper circuit operation. Supply start-up waveforms appear in Figure 7. Trace A, the nominal 5V rail, ramps for
3ms before arriving at 5V. During this interval, the LT1431
Single Supply, Grounded Cathode Current Source
Figure 5 preserves Figure 4’s grounded cathode operation
while operating from a single supply. This circuit is reminiscent of Figure 2, with a notable exception. Here, differential amplifier A2 senses across a shunt in the laser
anode, permitting cathode grounding. A2’s gain-scaled
output feeds back to A1 for loop closure. Loop compensation and enable input considerations are related to previous examples and, as before, Q1 could be replaced with a
switching regulator.
INPUT
0V TO 2.5V =
0mA TO 250mA
10k
0.02µF
5V
+
10k
330Ω
A1
LT1006
–
Q1
FZT-849
0.02µF
Q2
2N3904
* = 1% METAL FILM RESISTOR
= 1N4148
ENABLE
1V TO 5V = OFF
0V = ON
+
RG
A2
LT1789
RG
= 1N5712
= LASER
10k
1Ω
1%
–
22.2k*
A = 10
AN90 F05
Figure 5. Differentially Sensed Shunt Voltage Allows Grounded Cathode Laser Drive
with Single Supply. Loop and Enable Input Considerations Derive from Previous Figures
AN90-5
Application Note 90
2.5k
INPUT
0V TO 2.5V =
0mA TO 250mA
10k
5V
+
0.02µF
330Ω
A1
1/2 LT1013
10k
–
5V
Q1
FZT-849
5V
5V
0.02µF
1.5k*
470Ω
4.7k
50k
CLAMP
ADJUST
–
100Ω
A2
1/2 LT1013
Q3
2N3904
Q2
2N3906
+
LT1004
2.5V
10k
2.4k*
COLL
REF
+
CURRENT
CLAMP
A3
RG LT1789
RG
1Ω
1%
–
LT1431
1M
22.2k*
A = 10
2.5V
1N4001
GND
SELF-ENABLE
MBR0520
470Ω
1000pF
5V
5V
2N5060
0.1µF
* = 1% METAL FILM RESISTOR
187k*
+V
= 1N4148
FB1
= 1N5712
100k*
R
LTC1696
GND
OUT
560Ω
= LASER
AN90 F06
OPEN LASER PROTECTION
Figure 6. Figure 5’s Circuit, Augmented with “Self-Enable,” Monitors Power Supply,
Operates when VSUPPLY = 4V. Current and Open Laser Clamps Protect Laser
(trace B) follows the ramp, biasing Q3 on. A1’s output
(trace C) is uncontrolled during this period, Q1’s emitter
(trace D), however, is cut off due to Q3’s conduction and
cannot pass the disturbance. As a result, the laser conducts no current (trace E) during this time. When the
supply (trace A) ramps beyond 4V (just before the photo’s
4th vertical division), the LT1431 switches low (trace B),
Q3 switches off and the circuit “self-enables.” A1’s output
(trace C) ramps up, with Q1’s emitter (trace D) and laser
current (trace E) slaved to its movement. This action
prevents any undesired current in the laser during supply
turn on, regardless of unpredictable circuit behavior at low
supply voltages.
Supply turn on is not the only time laser current must be
controlled. Response to programming input changes must
be similarly well behaved. Figure 8 shows laser current
response (trace B) to a programming input step (trace A).
Damping is clean, with no hint of overshoot.
The circuit also includes open laser protection. If the
current source operates into an open load (no laser), it will
AN90-6
produce maximum voltage at the laser output terminals.
This circumstance can lead to “hot plugging” the laser, a
potentially destructive event. Intermittent laser connections can produce similar undesirable results. The LTC1696
overvoltage protection controller guards against open
laser operation. This device’s output latches high when its
feedback input (FB) exceeds 0.88V. Here, the FB pin is
biased so that laser output voltage exceeding 2.5V forces
the LTC1696 high, triggering the SCR to shunt current
away from the laser. The 470Ω resistor supplies SCR
holding current and the diodes insure no current flows in
the output.
Figure 9 details events with a properly connected laser at
supply turn on. Trace A is the supply, trace B the laser
voltage, trace C the LTC1696 output and trace D the laser
current. The waveforms show laser voltage (trace B) rising
to about 2V at supply turn on (trace A). Under these normal
conditions, the LTC1696 output (trace C) stays low and
laser current (trace D) rises to the programmed value.
Application Note 90
Figure 10 shows what happens when the circuit is turned
on into an open laser connection. Trace assignments are
identical to the previous photo. At supply turn on (trace A),
the laser voltage (trace B) transitions beyond the 2.5V
open laser threshold. The LTC1696 output (trace C) goes
high, the SCR latches and no current flows in the shunted
laser line (trace D). Once this occurs, power must be
recycled to reset the LTC1696-SCR latch. If the laser has
not been properly connected, the circuit will repeat its
protective action. Open laser protection is not restricted to
turn on. It will also act if laser connection is lost at any time
during normal circuit operation.
A final protection feature in Figure 6 is a current clamp. It
prevents uncontrolled programming inputs from being
transmitted by clamping them to a settable level. A2, Q2
and associated components form the clamp. Normally,
A2’s “+” input is above the circuit’s programming input
(Q2’s emitter voltage), A2’s output is high and Q2 is off. If
the programming input exceeds A2’s “+” input level, A2
swings low, Q2 comes on and the amplifier feedback
controls Q2’s emitter to the “clamp adjust” wiper potential. This clamps A1’s input to the “clamp adjust” setting,
preventing laser current overdrive. Clamp action need not
A = 5V/DIV
A = 1V/DIV
B = 5V/DIV
C = 2V/DIV
D = 2V/DIV
B = 20mA/DIV
E = 50mA/DIV
1ms/DIV
1ms/DIV
AN90 F07
Figure 7. Figure 6’s Waveforms During Power Supply
Application (Trace A). Traces B and C are LT1431 and A1
Outputs, Respectively. Q1’s Emitter (Trace D) Provides Power
Gain. Feedback Sets Laser Current (Trace E). Self-Enable
Circuit Prevents Spurious A1 Outputs (Trace C) During Supply
Ramp Up from Corrupting Laser Current (Trace E)
AN90 F08
Figure 8. Figure 6’s Output (Trace B) Responding
to Trace A’s Input Step. Trace B’s Laser Current
Has Controlled Damping, No Overshoot
A = 5V/DIV
A = 5V/DIV
B = 2V/DIV
B = 2V/DIV
C = 5V/DIV
C = 5V/DIV
D = 100mA/DIV
D = 1mA/DIV
500µs/DIV
AN90 F09
Figure 9. Figure 6’s Open Laser Protection Does Not Act
During Normal Turn On. Trace A is Supply, Trace B Laser
Voltage, Trace C LTC1696 Output and Trace D Laser Current.
LTC1696 Overvoltage Threshold is Not Exceeded, SCR is
Unbiased (Trace C) and Laser Conducts Current (Trace D)
500µs/DIV
AN90 F10
Figure 10. Open Laser Protection Circuit Responding to Open
Laser Turn On. Trace Assignments Identical to Previous Figure.
Laser Line (Trace B) Excursion Beyond Overvoltage Threshold
Causes LTC1696 Output (Trace C), Biasing SCR to Clamp Open
Laser Line. No Current Flows in Laser Line, Trace D (Note 100x
Increase in Measurement Sensitivity vs Figure 9)
AN90-7
Application Note 90
be particularly fast to be effective, because of A1’s 10k0.02µF input filter. Figure 11’s traces show clamp response to programming input overdrive. When the
programming input (trace A) exceeds the clamp’s preset
level, Q2’s emitter (trace B) does the same, causing A2’s
output (trace C) to swing down. A2 feedback controls Q2’s
emitter to the clamp level, arresting the voltage applied to
the 10k-0.02µF filter. The filter band limits the abrupt
clamp operation, resulting in a smooth corner at A1’s
positive input (trace D). A1’s clamped input dictates a
similarly shaped and clamped laser current (trace E). The
clamp remains active until the programming input falls
below the “clamp adjust” setting.
A = 2V/DIV
B = 1V/DIV
C = 5V/DIV
D = 1V/DIV
As shown, the circuit has the externally controlled enable
function, although Figure 6’s “self-enable” feature may be
used. Similarly, Figure 6’s current clamp and open laser
protection may be employed in this circuit.
This circuit’s switched mode energy delivery provides
high efficiency at high power but output noise may be an
issue. Residual harmonic content related to switching
regulator operation appears in the laser current. The
resultant low level modulation of laser output may be
troublesome in some applications. Figure 14 shows about
800µAP-P switching regulator related noise in the 2A laser
current output.2 This disturbance is composed of fundamental ripple and switching transition related harmonic.
This 0.05% noise is below most optical system requirements, although the following circuit achieves substantially lower noise figures.
0.001% Noise, 2A, Grounded Cathode Current Source
E = 100mA/DIV
500µs/DIV
AN90 F11
Figure 11. Figure 6’s Current Clamp Reacting to Programming
Input Overdrive. Waveforms Include Programming Input
(Trace␣ A), Q2 Emitter (Trace B), A2 Output (Trace C), A1 + Input
(Trace D) and Laser Current (Trace E). When Programming Input
Exceeds Clamp Threshold, A2 Swings Abruptly (Trace C),
Causing Q2’s Emitter (Trace B) to Clamp. A1’s +Input (Trace D)
Remains at Clamp Level, Maintaining Safe Laser Current
(Trace␣ E)
2.5A, Grounded Cathode Current Source
Figure 12, derived from Figures 3 and 6, provides up to
2.5A to a grounded cathode laser. A1 is the control
amplifier, output current is efficiently delivered by the
LT1506 switching regulator and A2 senses laser current
via a 0.1Ω shunt. Loop operation is similar to the descriptions given for Figures 3 and 6 with DC feedback to A1
coming from A2. Frequency compensation differs from
the previous figures. Stable loop operation is achieved by
local roll off at A1, augmented by two lead networks
associated with L1. Midband lead is provided by feeding
back a lightly filtered (1k-0.47µF) version of LT1506 VSW
output activity. High frequency lead, arriving via the 330Ω0.05µF pair, optimizes edge response. Figure 13’s wave-
AN90-8
forms detail dynamic response. Trace A’s input step
arrives in filtered form at A1’s positive input (trace B). The
loop produces trace C’s faithfully profiled laser current
output.
The previous circuit’s 0.05% noise content suits many
optical system applications. More stringent requirements
will benefit from Figure 15’s extremely low noise content.
This grounded cathode, 2A circuit has only 20µAP-P noise,
about 0.001%. Special switching regulator techniques are
used to attain this performance. Substantial noise reduction is achieved by limiting edge switching speed in the
regulator’s power stage.3 Voltage and current rise times in
switches Q1 and Q2 are controlled by the LT1683 pulse
width modulator. The LT1683’s output stage operates Q1
and Q2 in local loops which sense and control their edge
times. Transistor voltage information is fed back via the
4.7pF capacitors; current status is derived from the 0.033Ω
shunt and also fed back. This arrangement permits the
PWM control chip to fix transistor switching times, regardless of power supply or load changes. The transition
rates are set by resistors (RVSL and RCSL) associated with
Note 2: Noise contains no regularly occurring or coherent components. As such, switching regulator output “noise” is a misnomer.
Unfortunately, undesired switching related components in the
regulated output are almost always referred to as “noise.” Accordingly,
although technically incorrect, this publication treats all undesired
output signals as “noise.” See Reference 7.
Note 3: See Reference 7 for details on this technique.
Application Note 90
0.12µF
0.68µF
5V
VIN
3k
BOOST
1k
330Ω
0.05µF
L1 15µH
VSW
+
LTC1506
FB
0.47µF
MBR330
FROM OPTIONAL
OPEN LASER PROTECTION
CIRCUITRY OUTPUT.
SEE FIGURE 6
300µF
VC
2k
10k
INPUT
0V TO 2.5V =
0A TO 2.5A
1000pF
10k
–
330Ω
A1
LT1006
10k
+
10k
ENABLE
2N3904
0.33µF
FOR OPTIONAL
CURRENT CLAMP
SEE FIGURE 6
+
RG
* = 1% METAL FILM RESISTOR
L1 = COILTRONICS UP2C-150
A2
LT1789
RG
0.1Ω
1%
FOR OPTIONAL
SELF-ENABLE
SEE FIGURE 6
–
22.2k*
A = 10
= 1N4148
= 1N5712, UNLESS NOTED
AN90 F12
= LASER
Figure 12. Switched Mode Version of Figure 6 Has 2.5A Output.
Feedback Loop Compensation Accomodates Switching Regulator
Delay. Clamp, Protection and Self-Enable Circuits are Optional
A = 5V/DIV
A = 1mA/DIV
AC COUPLED
ON 2A DC
LEVEL
B = 0.5V/DIV
C = 0.5A/DIV
10ms/DIV
AN90 F13
Figure 13. 2.5A Current Source Waveforms for an Input
Step (Trace A). A1’s Input Filter (Trace B) Smooths Step,
Resulting in Trace C’s Similarly Shaped Laser Current
500ns/DIV
AN90 F14
Figure 14. High Power Current Source Noise Includes
Switching Regulator Fundamental Ripple and Harmonic
Content. 800µAP-P Noise is About 0.05% of 2A DC Output
AN90-9
Application Note 90
3Ω
≈ 8V
AT THIS
POINT
+
+
33µF
10µF
+
VIN
CAP +
68µF
GCL
V+
5V
LT1054
VOUT
GND
LT1683
V5
330Ω
GATE A
3.9k
SYNC
Q1
4.7pF
T1
CAP A
1200pF
12
9
33µF 2
5
11
8
L1
22µH
L2
22µH
+
14k
4.7pF
RT
4
1
5V
CT
1000pF
CAP B
+
+
330µF
330µF
15k
RVSL
10k
RCSL
Q2
GATE B
330Ω
0.1Ω
1%
1000pF
VC
PGND
FB
CS
1k
0.033Ω
0.01µF
1N5712
0.02µF
SHDN
SS GND NFB
10k
10k*
1000pF
* = 1% METAL FILM RESISTOR
L1, L2 = COILTRONICS UP-2B
0.01µF
T1 = COILTRONICS VP3-0780
ENABLE
A1
LT1006
Q3
+
10k
= MBR330, UNLESS NOTED
VIN
0V TO 2V
0A TO 2A
49.9k*
49.9k*
+
FOR OPTIONAL
CURRENT CLAMP
SEE FIGURE 6
= IRLZ34
Figure 15. 0.001% Noise, 2A Laser Current Source Has Grounded Cathode
Output. Clamp, Protection and Self-Enable Circuits May be Added
AN90-10
FOR OPTIONAL
SELF-ENABLE
SEE FIGURE 6
0.02µF
= SANYO OS-CON
= 2N3904
10k
–
10k
= 1N4148
= LASER
FROM OPTIONAL
OPEN LASER
PROTECTION OUTPUT.
SEE FIGURE 6
330Ω
AN90 F15
Application Note 90
the LT1683 controller. In practice, these resistor values
are set by adjusting them to minimize output noise. The
remainder of the circuit forms a grounded cathode laser
current source.
Q1 and Q2 drive T1, whose rectified output is filtered by LC
sections. Because T1’s secondary floats, the laser cathode and the 0.1Ω shunt may be declared at circuit ground.
The shunt is returned to T1’s secondary center tap,
completing a laser current flow path. This arrangement
produces a negative voltage corresponding to laser current at the shunt’s ungrounded end. This potential is
resistively summed at A1 with the positive voltage current
programming input information. A1’s output feedback
controls the LT1683’s pulse width drives to Q1 and Q2 via
Q3, closing a loop to set laser current. Loop compensation
is set by band limiting at A1 and Q3’s collector, aided by
a single lead network arriving from the L1-L2 junction.
Some circuit details merit attention. The LT1683’s supply
input pins are fed from an LT1054 based voltage multiplier. This boosted voltage provides enough gate drive to
ensure Q1-Q2 saturation. Damper networks across T1’s
rectifiers minimize diode switching related events in the
output current. Finally, this circuit is compatible with the
“self-enable” and laser protection features previously
described. Appropriate connection points appear in the
figure.
The speed controlled switching times result in a spectacular decrease in noise. Figure 16 shows just 20µAP-P noise,
about 0.001% of the 2A DC laser current. Fundamental
ripple residue and switching artifacts are visible against
the measurement noise floor.4
0.0025% Noise, 250mA,
Grounded Anode Current Source
This circuit, similar to the previous one, uses edge time
control to achieve an exceptionally low noise output. It is
intended for lower power lasers requiring grounded anode
operation. The LT1533, a version of the previous circuit’s
LT1683, has internal power switches. These switches
drive T1. T1’s rectified and filtered secondary produces a
negative output, biasing the laser. The laser’s anode is
grounded and its current path to T1’s secondary completed via the 1Ω shunt. This configuration makes T1’s
center tap voltage positive and proportional to laser current. This voltage is compared by A1 to the current
programming input. A1 biases Q2, closing a loop around
the LT1533. Loop compensation is provided by local
bandwidth limiting at A1 and Q2’s collector damping and
feedback capacitors.
This circuit’s 2.5µAP-P noise qualifies it for the most
demanding applications. Figure 18 shows residual switching related noise approaching the measurement noise
floor.
The enable function operates as previously described.
Additionally, this circuit is compatible with Figure 6’s
“self-enable” and laser protection accessory circuits.
Changes necessitated by the grounded anode operation
appear on the schematic.
A = 20µA/DIV
AC COUPLED
ON 2A DC
LEVEL
2µs/DIV
AN90 F14
Figure 16. Figure 15’s Output Noise Measures ≈20µAP-P, About 0.001%. Coherent,
Identifiable Components Include Fundamental Ripple Residue and Switching Artifacts
Note 4: Reliable wideband current noise measurement at these levels
requires special techniques. See Appedix B, “Verifying Switching
Regulator Related Noise” and Appendix C, “Notes on Current Probes
and Noise Measurement,” for details.
AN90-11
Application Note 90
L3
22nH
820pF
PGND
T1
CT
COL A
RT
FB
10
3
1k
5V
LT1533
RCSL
RVSL
14k
VC
10k
33µF
1Ω
1%
0.01µF
TO LT1533
SHUTDOWN PIN
35.7k*
1N5712
Q1
2N3904
= 1% METAL FILM RESISTOR
= COILTRONICS CTX300-2
= COILCRAFT DT1608C-333B
= COILCRAFT B07T
= COILTRONICS CTX02-13834
0.033µF
Q2
2N3904
33µF
SHDN
10k
ENABLE
*
L1
L2
L3
T1
9
14k
10k
FOR OPTIONAL
SELF-ENABLE
SEE FIGURE 6
L2
33µH
0.01µF
7
4
COL B
FROM OPTIONAL
OPEN LASER
PROTECTION.
SEE FIGURE 6
5
L1
300µH
22k
12
2
+
3.9k
16k
+
5V
1k
TO LTC1696
FB PIN.
SEE FIGURE 6
+
10k
–
100k*
A2
LT1006
+
OPTIONAL OPEN
LASER PROTECTION.
SEE FIGURE 6 FOR
REMAINDER OF CIRCUITRY.
DELETE 2N5060
A1
LT1006
–
= 1N4148
= BAT85
= LASER
INPUT
0V TO 2.5V =
0mA TO 250mA
10k*
80.6k*
1000pF
0.1µF
FOR OPTIONAL
CURRENT CLAMP
SEE FIGURE 6
10k*
AN90 F17
Figure 17. 0.0025% Noise, Grounded Anode Laser Current Source is 250mA Version of Figure 15
A = 5µA/DIV
AC COUPLED
ON 100mA
DC LEVEL
2µs/DIV
AN90 F14
Figure 18. Figure 17’s 2.5µAP-P Switching Related
Noise is Detectable in Measurement Noise Floor
AN90-12
Application Note 90
Low Noise, Fully Floating Output Current Source
The schematic shows the LT1533 low noise switching
regulator driving T1. The LT1533, while retaining its
controlled edge time characteristics, is forced to run at
50% duty cycle by grounding its “duty” pin. Current flows
through Q1 and the 0.1Ω shunt into T1’s primary. The
LT1533 open collector power outputs alternately chop
primary current to ground. Primary current magnitude,
and hence the 0.1Ω shunt voltage, is set by Q1’s bias. Q1’s
bias, in turn, is set by A1’s output, which represents the
Figure 19 retains the preceding example’s low noise but
also has a fully floating output. Either laser terminal may
be grounded without effecting circuit operation. This
feature is realized by feedback controlling transformer
primary current and relying on interwinding coupling to
maintain regulation.5 This coupling varies slightly with
operating point, limiting output current regulation to
about␣ 1%.
3.3V
0.1Ω
1%
Q1
FZT-849
+
100µF
820pF
15k
16k
RT
CT
VSL
15k
T1
CSL
COL A
3
2
LT1533
5
4
COL B
FB
DUTY
10k
20k
10
12
L1
300µH
7
L2
33µH
+
+
33µF
33µF
9
PGND
L3
22nH
3.3V
1000pF
R
+V
LTC1696
FB1
OUT
+
RG
–
8.76k*
GND
ENABLE
FOR OPTIONAL SELF-ENABLE
CIRCUIT, SEE FIGURE 6.
CHANGE 1.5k RESISTOR AT
LT1431 TO 475Ω 1%
9.5k*
A = 22
10k
A1
LT1006
10k
+
Q2
2N3904
0.2µF
10k
OPEN LASER PROTECTION
–
A2 RG
LT1789
0.1µF
7.15k*
OPTIONAL CURRENT
CLAMP CIRCUIT.
SEE FIGURE 6
10k
*
L1
L2
L3
T1
= 1% METAL FILM RESISTOR
= COILTRONICS CTX300-2
= COILCRAFT DT1608C-333B
= COILCRAFT B07T
= COILTRONICS CTX02-13834
= 1N4148
INPUT
0V TO 1.5V =
0mA TO 150mA
= LASER
AN90 F19
Figure 19. Switched Mode, Low Noise Current Source Has Floating Output, Permitting Grounding Laser Anode or
Cathode. Open Laser Protection is Included; Circuit is Compatible with Current Clamp and Self-Enable Options
Note 5: We have engaged this stunt before to serve a variety of
purposes. See References 2, 3 and 4.
AN90-13
Application Note 90
difference between the output current programming input
and A2’s amplified version of the shunt voltage. This loop
enforces a shunt voltage proportionate to current programming input value. In this way, the current programming input sets T1 primary current, determining T2
secondary current through the laser. Current programming input scaling is calibrated by differential amplifier
A2’s gain setting resistor.
Because the LTC1696 output latches, power must be
recycled to reset the circuit. If the laser has not been
connected, the latch will act again, protecting the laser
from “hot plugging” or intermittent connections. The
“self-enable” and current clamp options may be added in
accordance with the notations on the schematic.
The primary side feedback’s lack of global feedback mandates current regulation compromise. Figure 20’s plot of
laser current vs programming input voltage shows 1%
conformance over nearly the entire range. The error below
10mA, due to nonideal transformer behavior, is normally
insignificant because it is below typical laser threshold
current. Line regulation, also degraded by the sensing
scheme, still maintains about 0.05%/V. Similarly, load
regulation, over a 1V to 1.8V compliance voltage, is
typically 2%.
Figure 21’s current source is useful where the laser anode
is committed to the power supply. A1, sensing Q1’s
emitter, closes a loop which forces constant current in the
laser. Local compensation at A1 and input band limiting
stabilize the loop.
LASER CURRENT IN MILLIAMPERES
This circuit’s floating output complicates inclusion of the
laser protection and “self-enable” features described in
Figure 6’s text but they are accommodated. Open laser
protection, shown in Figure 20, is accomplished by biasing the LTC1696 from T1’s center tap. If the laser opens,
the loop forces a marked rise at T1’s center tap, latching
the LTC1696’s output high. This skews A1’s inputs, sending its output low and shutting off Q1. All T1 drive ceases.
150
140
130
120
110
100
90
80
70
60
50
40
30
20
10
0
Anode-at-Supply Current Source
This circuit also includes an inherent “self-enable” feature.
The LT1635 operates at supply voltages down to 1.2V.
Above 1.2V the LT1635’s comparator configured section
(C1) holds off circuit output until supply voltage reaches
2V. Below 1.2V supply, Q1’s base biasing prevents unwanted outputs. Figure 22 details operation during supply
turn on. At supply ramp up (trace A), output current
(trace␣ D) is disabled. When the supply reaches 2V, C1
(trace B) goes low, permitting A1’s output (trace C) to rise.
This biases Q1 and laser current flows (trace D). The
LT1635 operates on supply voltages as low as 1.2V. Below
this level, spurious outputs are prevented by junction
stacking and band limiting at Q1’s base. Q1’s base compo-
TYPICAL LASER
THRESHOLD
CURRENT
0.1
0.3 0.5 0.7 0.9 1.1 1.3
INPUT PROGRAMMING VOLTAGE
1.5
AN90 F20
Figure 20. Laser Current vs Input Programming Voltage for Floating Current Source.
Conformance is within 1% over Nearly Entire Range. Error Below 10mA, Due to
Nonideal Transformer Behavior, is Below Typical Laser Threshold Current
AN90-14
Application Note 90
nents also prevent unwanted outputs when the supply
rises rapidly. Such rapid rise could cause uncontrolled A1
outputs before the amplifier and its feedback loop are
established. Figure 23 shows circuit events during a rapid
supply rise. Trace A shows the supply’s quick ascent.
Trace B, C1’s output, responds briefly but goes low some
time after the supply moves past 2V. A1 (trace C) produces
an uncontrolled output for about 100µs. The RC combination in Q1’s base line filters this response to insignificant
levels and no laser current (trace D) flows.
FOR OPTIONAL
CURRENT CLAMP
SEE FIGURE 6
3.3V
CURRENT
SOURCE
3.3V
90.9k*
INPUT
0V TO 1.5V =
0mA TO 150mA
10K*
BAT85
+
0.1µF
A1
1/2 LT1635
100Ω
–
10µF
+
0.2µF
3.3V
18k
NC
2N3904
Q1
2N2222
3k
10k
FB
1N5711
C1
1/2 LT1635
2k
200mV
2k
+
1Ω
1%
16.5k*
TO OPTIONAL
OPEN LASER
8.87k* PROTECTION AT
LTC1696 FB PIN.
SEE FIGURE 6
SELF-ENABLE
* = 1% METAL FILM RESISTOR
= 1N4148, UNLESS NOTED
= LASER
AN90 F21
Figure 21. Circuit Has Laser Anode Committed to Supply, Inherent Self-Enabled
Operation. LT1635 Functions at 1.2V, Although Self-Enable Feature Holds Off Output
Until Power Supply Exceeds 2V. Current Clamp and Open Laser Protection are Optional
A = 2V/DIV
A = 2V/DIV
B = 2V/DIV
B = 1V/DIV
C = 1V/DIV
C = 0.5V/DIV
D = 10mA/DIV
D = 50mA/DIV
10ms/DIV
AN90 F22
Figure 22. Output Current (Trace D) is Held Off Until
Supply (Trace A) Ramps Past 2V. Self-Enable
Comparator (Trace B) Operates Above 1.2V; Q1 Base
(Trace C) Biasing Prevents Output Below 1.2V
50µs/DIV
AN90 F23
Figure 23. Rapidly Rising Supply (Trace A) Produces No
Current Output (Trace D) Despite A1’s Transient Uncontrolled
Output (Trace C). C1 (Trace B) Reacts Properly but A1’s
Inactive Loop Cannot Respond. Q1’s Base Line Components
Preclude Spurious Current Output (Trace D)
AN90-15
Application Note 90
The slew retarded input and loop compensation yield clean
dynamic response with no overshoot. Figure 24, trace A,
is an input step. This step, filtered at A1’s input (trace B),
is represented as a well controlled laser current output in
trace C.
Current clamping and open laser protection options are
annotated in the schematic. Additionally, higher output
current is possible at increased supply voltages, although
Q1’s dissipation limits must be respected.
A = 1V/DIV
B = 1V/DIV
C = 50mA/DIV
5ms/DIV
AN90 F24
Figure 24. Output Current (Trace C) Responds Cleanly
to Filtered Version (Trace B) of Trace A’s Input Step
Note: This application note was derived from a manuscript originally
prepared for publication in EDN magazine.
REFERENCES
1. Hewlett-Packard Company, “Model 6181C Current
Source Operating and Service Manual,” 1975.
5. Grafham, D. R., “Using Low Current SCRs,” General
Electric Co, AN-200.19, January 1967.
2. Williams, J., “Designing Linear Circuits for 5V Single
Supply Operation,” “Floating Output Current Loop
Transmitter,” Linear Technology Corporation, Application Note 11, September 1985, p. 10.
6. General Electric Co., “SCR Manual,” 1967.
3. Williams, J., “A Fourth Generation of LCD Backlight
Technology,” “Floating Lamp Circuits,” Linear Technology Corporation, Application Note 65, November
1995, pp. 40–42.
8. Pope, A., “An Essay on Criticism,” 1711.
4. Linear Technology Corporation, “LT1182/LT1183/
LT1184/LT1184F CCFL/LCD Contrast Switching Regulators,” Data Sheet, 1995.
AN90-16
7. Williams, J., “A Monolithic Switching Regulator with
100µV Output Noise,” Linear Technology Corporation, Application Note 70, October 1997.
Application Note 90
APPENDIX A
SIMULATING THE LASER LOAD
Electronic Laser Load Simulator
Fiber optic lasers are a delicate, unforgiving and expensive
load. This is a poisonous brew when breadboarding with
high likelihood of catastrophe. A much wiser alternative is
to simulate the laser load using either diodes or electronic
equivalents. Lasers look like junctions with typical forward
voltages ranging from 1.2V to 2.5V. The simplest way to
simulate a laser is to stack appropriate numbers of diodes
in series. Figure A1 lists typical junction voltages at
various currents for two popular diode types. The MR750
is suitable for currents in the ampere range, while the
1N4148 serves well at lower currents. Typically, stacking
two to three diodes allows simulating the laser in a given
current range. Diode voltage tolerances and variations due
to temperature and current changes limit accuracy, although results are generally satisfactory.
Figure A2 is a laser load simulator powered by a 9V battery.
It eliminates diode load junction voltage drop uncertainty.
Additionally, any desired “junction drop” voltage may be
conveniently set with the indicated potentiometer. Electronic feedback enforces establishment and maintenance
of calibrated junction drop equivalents.
The potentiometer sets a voltage at A1’s negative input. A1
responds by biasing Q1. Q1’s drain voltage controls Q2’s
base and, hence, Q2’s emitter potential. Q2’s emitter is fed
back to A1, closing a loop around the amplifier. This forces
the voltage across Q2 to equal the potentiometer’s output
voltage under all conditions. The capacitors at A1 and Q1
stabilize the loop and Q2’s base resistor and ferrite bead
suppress parasitic oscillation. The 1N5400 prevents Q1Q2 reverse biasing if the load terminals are reversed.
MR750 (25°C)
TYPICAL JUNCTION CURRENT
TYPICAL JUNCTION VOLTAGE
1N4148 (25°C)
TYPICAL JUNCTION CURRENT
TYPICAL JUNCTION VOLTAGE
0.5A
0.68V
0.1A
0.83V
1.0A
0.76V
0.2A
0.96V
1.5A
0.84V
0.3A
1.08V
2.0A
0.90V
2.5A
0.95V
Figure A1. Characteristics of Diodes Suitable for Simulating Lasers.
Appropriate Series Connections Approximate Laser Forward Voltage
100k
OUT +
3A MAX
10k
9V
9V
100k
9V
“JUNCTION
DROP” = 0 To 2.5V
+
0.01µF
1k
LT1077
10Ω
Q1
VN2222L
Q2
D45VH10
(HEAT
SINK)
1N5400
–
1M
100k
LT1004
2.5V
0.001µF
= FERRITE BEAD, FERRONICS #21-110J
OUT –
AN90 FA02
Figure A2. Floating, Battery-Powered Laser Simulator Sets Desired “Junction Drop”
Across Output Terminals. Amplifier Feedback Controls Q2’s VCE to Potentiometer Voltage
AN90-17
Application Note 90
APPENDIX B
VERIFYING SWITCHING REGULATOR RELATED NOISE
Measuring the switching regulator related current noise
levels discussed in the text requires care. The microamp
amplitudes and wide bandwidth of interest (100MHz)
mandates strict attention to measurement technique. In
theory, simply measuring voltage drop across a shunt
resistor permits current to be determined. In practice, the
resultant small voltages and required high frequency
fidelity pose problems. Coaxial probing techniques are
applicable but probe grounding requirements become
severe. The slightest incidence of multiple ground paths
(“ground loops”) will corrupt the measurement, rendering
observed “results” meaningless. Differentially configured
coaxial probes offer some relief from ground loop based
difficulties but there is an inherently better approach.1
Current transformers offer an attractive way to measure
noise while eliminating probe grounding concerns. Two
types of current probes are available: split core and closed
core. The split core “clip on” types are convenient to use
but have relatively low gain and a higher noise floor than
closed core types.2 The closed core transformer’s gain
and noise floor advantages are particularly attractive for
wideband, low current measurement.
Figure B1’s test setup allows investigation of the closed
core transformer’s capabilities. The transformer specified
has flat gain over a wide bandwidth, a well shielded
enclosure and a coaxial 50Ω output connection. Its 5mV/
mA output feeds a low noise x100, 50Ω input amplifier.
The amplifier’s terminated output is monitored by an
oscilloscope with a high sensitivity plug-in. A 1V pulse
driving a known resistor value (“R”) provides a simple way
to source calibrated current into the transformer.
If R = 10k, resultant pulsed current is 100µA. Figure B2’s
oscilloscope photo shows test setup response. The waveform is crisp, essentially noise free and agrees with
predicted amplitude. More sensitive measurement involves determining the test setup’s noise floor. Figure B3,
taken with no current flowing in the transformer, indicates
a noise limit of about 10µAP-P. Most of this noise is due to
the x100 amplifier.
The preceding exercise determines the test setup’s gain
and noise performance. This information provides the
confidence necessary to make a meaningful low level
current measurement. Figure B4, taken with Figure B1’s
R␣ =␣ 100k, sources only 10µA to the transformer. This is
TYPE 547 OSCILLOSCOPE
TYPE 1A5
5mV/mA
1V
PULSE
INPUT
R
R = 10k = 100µA
R = 100k = 10µA
TEKTRONIX
CLOSED CORE
CURRENT PROBE
#CT-1
HP-461A
AMPLIFIER
X100
50Ω
TERMINATOR
0.5V/mA
LOW NOISE
AMPLIFIER
AN90 FB01
Figure B1. Noise Measurement Instrumentation Includes Resistors, Closed
Core Current Probe, Low Noise Wideband Amplifier and Oscilloscope
Note 1: This is not to denigrate low level voltage probing methods.
Their practice is well refined and directly applicable in appropriate
circumstances. See Appendix C in Reference 7 for tutorial.
AN90-18
Note 2: See Appendix C, “Notes on Current Probes and Noise
Measurement,” for a detailed comparison.
Application Note 90
comparable to the previously determined noise floor but
the trace, clearly delineated against the noise limit, indicates a 10µA amplitude. This level of agreement qualified
this test method to obtain the text’s quoted noise figures.
Isolated Trigger Probe
The performance limits noted above were determined with
a well defined, pulsed input test signal. Residual switching
regulator noise has a much less specific profile. The
oscilloscope may encounter problems triggering on an illdefined, noise laden waveform. Externally triggering the
’scope from the switching regulator’s clocking solves this
problem but introduces ground loops, corrupting the
measurement.3 It is possible, however, to externally trigger the ’scope without making any galvanic connections to
the circuit, eliminating ground loop concerns. This is
A = 100µA/DIV
accomplished by coupling to the field produced by the
switching regulator magnetics. A probe which does this is
simply an RF choke terminated against ringing (Figure
B5). The choke, appropriately positioned, picks up residual switching frequency related magnetic field, generating an isolated trigger signal.4 This arrangement furnishes
a ’scope trigger signal with essentially no measurement
corruption. The probe’s physical form appears in Figure
B6. For good results, the termination should be adjusted
for minimum ringing while preserving the highest possible amplitude output. Light compensatory damping produces Figure B7’s output, which will cause poor ’scope
triggering. Proper adjustment results in a more favorable
output (Figure B8), characterized by minimal ringing and
well defined edges.
A = 10µA/DIV
100ns/DIV
100ns/DIV
AN90 FB02
Figure B2. Response to a 100µA Input is Clean.
Displayed Amplitude Agrees with Input Stimulus,
Indicating Calibrated Measurement
AN90 FB03
Figure B3. 10µA Noise Floor is Determined by
Removing Current Loop from Transformer. Remaining
Noise is Primarily Due to x100 Amplifier
L1
PROBE
SHIELDED
CABLE
TERMINATION BOX
BNC
OUTPUT
A = 10µA/DIV
BNC CONNECTION
TO TERMINATION BOX
L1: J.W. MILLER #100267
100ns/DIV
1k DAMPING
ADJUST
4700pF
AN90 FB05
AN90 FB04
Figure B4. Verifying Gain Near Noise Floor. 10µA Input
Pulse Produces Calibrated, Readily Discernable Output
Note 3: See previous comments at the beginning of this appendix.
Figure B5. Simple Trigger Probe Eliminates
Board Level Ground Loops. Termination Box
Components Damp L1’s Ringing Response
Note 4: Veterans of LTC application notes, a hardened crew, will
recognize this probe’s description from LTC Application Note 70
(Reference 7). It directly applies to this topic and is reproduced here
for reader convenience.
AN90-19
Application Note 90
Trigger Probe Amplifier
The field around the switching magnetics is small and may
not be adequate to reliably trigger some oscilloscopes. In
such cases, Figure B9’s trigger probe amplifier is useful.
It uses an adaptive triggering scheme to compensate for
variations in probe output amplitude. A stable 5V trigger
output is maintained over a 50:1 probe output range. A1,
operating at a gain of 100, provides wideband AC gain. The
output of this stage biases a 2-way peak detector (Q1
through Q4). The maximum peak is stored in Q2’s emitter
capacitor, while the minimum excursion is retained in Q4’s
emitter capacitor. The DC value of the midpoint of A1’s
output signal appears at the junction of the 500pF capacitor and the 3MΩ units. This point always sits midway
between the signal’s excursions, regardless of absolute
amplitude. This signal-adaptive voltage is buffered by A2
to set the trigger voltage at the LT1394’s positive input.
The LT1394’s negative input is biased directly from A1’s
output. The LT1394’s output, the circuit’s trigger output,
is unaffected by >50:1 signal amplitude variations. An
x100 analog output is available at A1.
Figure B10 shows the circuit’s digital output (trace B)
responding to the amplified probe signal at A1 (trace A).
Figure B6. The Trigger Probe and Termination Box. Clip
Lead Facilitates Positioning Probe, is Electrically Neutral
AN90-20
Application Note 90
10mV/DIV
10mV/DIV
10µs/DIV
10µs/DIV
AN90 FB07
Figure B7. Misadjusted Termination Causes Inadequate
Damping. Unstable Oscilloscope Triggering May Result
AN90 FB08
Figure B8. Properly Adjusted Termination
Minimizes Ringing with Small Amplitude Penalty
50Ω
ANALOG BNC OUTPUT
5V
2k
3
Q1
6
4
+
3M
500pF
0.005µF
A1
LT1227
5V
+
0.005µF
–
750Ω
Q2
2
5V
2k
5
1
–
13
1k
Q3
5V
15
10Ω
3M
10
14
12
A2
LT1006
Q4
11
470Ω
+
+
10µF
0.1µF
100µF
0.1µF
+
2k
0.1µF
470Ω
Q1, Q2, Q3, Q4 = CA3096 ARRAY: TIE SUBSTRATE (PIN 16) TO GROUND
= 1N4148
–
LT1394
DIGITAL
TRIGGER
OUT BNC
TO ’SCOPE
AN90 FB09
TRIGGER PROBE
AND TERMINATION BOX
(SEE FIGURE B5 FOR DETAILS)
Figure B9. Trigger Probe Amplifier Has Analog and Digital Outputs. Adaptive
Threshold Maintains Digital Output over 50:1 Probe Signal Variations
A = 1V/DIV
AC COUPLED
B = 5V/DIV
10µs/DIV (UNCALIB)
AN90 FB10
Figure B10. Trigger Probe Amplifier Analog
(Trace A) and Digital (Trace B) Outputs
AN90-21
Application Note 90
APPENDIX C
NOTES ON CURRENT PROBES AND
NOISE MEASUREMENT
Appendix B explained current probes advantages in switching regulator related current noise measurement. Their
minimally invasive nature eases connection parasitics,
enhancing measurement fidelity. Different combinations
of current probes and amplifiers provide varying degrees
of performance and convenience. Figure C1 summarizes
characteristics for two probes and applicable amplifiers.
In general, the noise floor uncertainties of the convenient
split core types are compromised by their construction.
The closed core probes are less noisy and some types
have inherently higher gain, a distinct advantage. A laboratory based comparison is revealing.
CURRENT
PROBE
AMPLIFIER
Tektronix
P6022
(1mV/mA)
Preamble
1855
(1MΩ)
Tektronix Hewlett-Packard
CT-1
461A
(5mV/mA)
(50Ω)
Figure C2 shows the CT-1 (closed core)-HP461A combination responding to a 100µA pulsed input. The waveform
is clearly outlined, with pulse top and bottom trace thickening deriving from the noise floor.1 Figure C3, taken with
the same input, is degraded. The split core P6022-Preamble 1855 combination used has much greater noise.
The decreased performance is almost entirely due to the
split core probe’s construction.
In closing, it is worthwhile noting that Hall element stabilized current probes (e.g., Tektronix AM503, P6042) are
not suitable for low level measurement. The Hall device
based flux nulling loop extends probe response to DC but
introduces ≈300µA of noise.
NOISE
FLOOR
(100 MHz BW) COMMENTS
100µA
Split Core is Convenient to Use but Sensitivity is Low,
Resulting in Relatively High Overall Noise Floor
15µA
Probe’s Higher Gain Accounts for Most Noise Floor Reduction—
50Ω Input Amplifier Provides Some Additional Benefit.
Closed Core Probe Requires Breaking Conductor to Make Measurement
Figure C1. Recommended Instrumentation for Current Noise
Measurement. Split Core “Current Probe” is Convenient;
Closed Core Provides Higher Gain and Lower Noise
Note 1: Diehard curmudgeons still using high quality analog
oscillscopes routinely discern noise presence due to trace thickening.
Those stuck with modern instruments routinely view thick, noisy
traces.
AN90-22
Application Note 90
A = 100µA/DIV
500ns/DIV
Figure C2. CT-1/HP-461A Combination Clearly
Displays a 100µA Pulse Train. Noise Floor Causes
Slight Pulse Top and Bottom Trace Thickening
A = 100µA/DIV
500ns/DIV
Figure C3. P6022/Preamble 1855 Presentation
of Previous Figure’s Waveform Has Degraded
Signal-to-Noise Performance. Split Core
“Current Probe” Convenience Necessitates
Measurement Fidelity Compromise
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
AN90-23
Application Note 90
AN90-24
Linear Technology Corporation
an90f LT/TP 0402 2K • PRINTED IN USA
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